Structure of 13Be probed via secondary beam reactions

Abstract

The low-lying level structure of the unbound neutron-rich nucleus 13Be has been investigated via breakup on a carbon target of secondary beams of 14,15B at 35 MeV/nucleon. The coincident detection of the beam velocity 12Be fragments and neutrons permitted the invariant mass of the 12Be+n and 12Be+n+n systems to be reconstructed. In the case of the breakup of 15B, a very narrow structure at threshold was observed in the 12Be+n channel. Contrary to earlier stable beam fragmentation studies which identified this as a strongly interacting s-wave virtual state in 13Be, analysis here of the 12Be+n+n events demonstrated that this was an artifact resulting from the sequential-decay of the 14Be(2+) state. Single-proton removal from 14B was found to populate a broad low-lying structure some 0.70 MeV above the neutron-decay threshold in addition to a less prominent feature at around 2.4 MeV. Based on the selectivity of the reaction and a comparison with (0-3)ω shell-model calculations, the low-lying structure is concluded to most probably arise from closely spaced Jπ=1/2+ and 5/2+ resonances (Er=0.400.03 and 0.85+0.15-0.11 MeV), whilst the broad higher-lying feature is a second 5/2+ level (Er=2.350.14 MeV). Taken in conjunction with earlier studies, it would appear that the lowest 1/2+ and 1/2- levels lie relatively close together below 1 MeV.